/* * Copyright (C) 2018 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #define LOG_TAG "neuralnetworks_hidl_hal_test" #include "VtsHalNeuralnetworks.h" #include "Callbacks.h" namespace android { namespace hardware { namespace neuralnetworks { namespace V1_2 { using V1_0::OperandLifeTime; using V1_1::ExecutionPreference; namespace vts { namespace functional { using ::android::hardware::neuralnetworks::V1_2::implementation::ExecutionCallback; using ::android::hardware::neuralnetworks::V1_2::implementation::PreparedModelCallback; using HidlToken = hidl_array(Constant::BYTE_SIZE_OF_CACHE_TOKEN)>; ///////////////////////// UTILITY FUNCTIONS ///////////////////////// static void validateGetSupportedOperations(const sp& device, const std::string& message, const Model& model) { SCOPED_TRACE(message + " [getSupportedOperations_1_2]"); Return ret = device->getSupportedOperations_1_2(model, [&](ErrorStatus status, const hidl_vec&) { EXPECT_EQ(ErrorStatus::INVALID_ARGUMENT, status); }); EXPECT_TRUE(ret.isOk()); } static void validatePrepareModel(const sp& device, const std::string& message, const Model& model, ExecutionPreference preference) { SCOPED_TRACE(message + " [prepareModel_1_2]"); sp preparedModelCallback = new PreparedModelCallback(); ASSERT_NE(nullptr, preparedModelCallback.get()); Return prepareLaunchStatus = device->prepareModel_1_2(model, preference, hidl_vec(), hidl_vec(), HidlToken(), preparedModelCallback); ASSERT_TRUE(prepareLaunchStatus.isOk()); ASSERT_EQ(ErrorStatus::INVALID_ARGUMENT, static_cast(prepareLaunchStatus)); preparedModelCallback->wait(); ErrorStatus prepareReturnStatus = preparedModelCallback->getStatus(); ASSERT_EQ(ErrorStatus::INVALID_ARGUMENT, prepareReturnStatus); sp preparedModel = getPreparedModel_1_2(preparedModelCallback); ASSERT_EQ(nullptr, preparedModel.get()); } static bool validExecutionPreference(ExecutionPreference preference) { return preference == ExecutionPreference::LOW_POWER || preference == ExecutionPreference::FAST_SINGLE_ANSWER || preference == ExecutionPreference::SUSTAINED_SPEED; } // Primary validation function. This function will take a valid model, apply a // mutation to it to invalidate the model, then pass it to interface calls that // use the model. Note that the model here is passed by value, and any mutation // to the model does not leave this function. static void validate(const sp& device, const std::string& message, Model model, const std::function& mutation, ExecutionPreference preference = ExecutionPreference::FAST_SINGLE_ANSWER) { mutation(&model); if (validExecutionPreference(preference)) { validateGetSupportedOperations(device, message, model); } validatePrepareModel(device, message, model, preference); } // Delete element from hidl_vec. hidl_vec doesn't support a "remove" operation, // so this is efficiently accomplished by moving the element to the end and // resizing the hidl_vec to one less. template static void hidl_vec_removeAt(hidl_vec* vec, uint32_t index) { if (vec) { std::rotate(vec->begin() + index, vec->begin() + index + 1, vec->end()); vec->resize(vec->size() - 1); } } template static uint32_t hidl_vec_push_back(hidl_vec* vec, const Type& value) { // assume vec is valid const uint32_t index = vec->size(); vec->resize(index + 1); (*vec)[index] = value; return index; } static uint32_t addOperand(Model* model) { return hidl_vec_push_back(&model->operands, { .type = OperandType::INT32, .dimensions = {}, .numberOfConsumers = 0, .scale = 0.0f, .zeroPoint = 0, .lifetime = OperandLifeTime::MODEL_INPUT, .location = {.poolIndex = 0, .offset = 0, .length = 0}, }); } static uint32_t addOperand(Model* model, OperandLifeTime lifetime) { uint32_t index = addOperand(model); model->operands[index].numberOfConsumers = 1; model->operands[index].lifetime = lifetime; return index; } ///////////////////////// VALIDATE MODEL OPERAND TYPE ///////////////////////// static const uint32_t invalidOperandTypes[] = { static_cast(OperandTypeRange::FUNDAMENTAL_MIN) - 1, static_cast(OperandTypeRange::FUNDAMENTAL_MAX) + 1, static_cast(OperandTypeRange::OEM_MIN) - 1, static_cast(OperandTypeRange::OEM_MAX) + 1, }; static void mutateOperandTypeTest(const sp& device, const Model& model) { for (size_t operand = 0; operand < model.operands.size(); ++operand) { for (uint32_t invalidOperandType : invalidOperandTypes) { const std::string message = "mutateOperandTypeTest: operand " + std::to_string(operand) + " set to value " + std::to_string(invalidOperandType); validate(device, message, model, [operand, invalidOperandType](Model* model) { model->operands[operand].type = static_cast(invalidOperandType); }); } } } ///////////////////////// VALIDATE OPERAND RANK ///////////////////////// static uint32_t getInvalidRank(OperandType type) { switch (type) { case OperandType::FLOAT16: case OperandType::FLOAT32: case OperandType::INT32: case OperandType::UINT32: case OperandType::BOOL: return 1; case OperandType::TENSOR_BOOL8: case OperandType::TENSOR_FLOAT16: case OperandType::TENSOR_FLOAT32: case OperandType::TENSOR_INT32: case OperandType::TENSOR_QUANT8_ASYMM: case OperandType::TENSOR_QUANT8_SYMM: case OperandType::TENSOR_QUANT16_ASYMM: case OperandType::TENSOR_QUANT16_SYMM: case OperandType::TENSOR_QUANT8_SYMM_PER_CHANNEL: return 0; default: return 0; } } static void mutateOperandRankTest(const sp& device, const Model& model) { for (size_t operand = 0; operand < model.operands.size(); ++operand) { const uint32_t invalidRank = getInvalidRank(model.operands[operand].type); if (invalidRank == 0) { continue; } const std::string message = "mutateOperandRankTest: operand " + std::to_string(operand) + " has rank of " + std::to_string(invalidRank); validate(device, message, model, [operand, invalidRank](Model* model) { model->operands[operand].dimensions = std::vector(invalidRank, 0); }); } } ///////////////////////// VALIDATE OPERAND SCALE ///////////////////////// static float getInvalidScale(OperandType type) { switch (type) { case OperandType::FLOAT16: case OperandType::FLOAT32: case OperandType::INT32: case OperandType::UINT32: case OperandType::BOOL: case OperandType::TENSOR_BOOL8: case OperandType::TENSOR_FLOAT16: case OperandType::TENSOR_FLOAT32: case OperandType::TENSOR_QUANT8_SYMM_PER_CHANNEL: return 1.0f; case OperandType::TENSOR_INT32: return -1.0f; case OperandType::TENSOR_QUANT8_SYMM: case OperandType::TENSOR_QUANT8_ASYMM: case OperandType::TENSOR_QUANT16_ASYMM: case OperandType::TENSOR_QUANT16_SYMM: return 0.0f; default: return 0.0f; } } static void mutateOperandScaleTest(const sp& device, const Model& model) { for (size_t operand = 0; operand < model.operands.size(); ++operand) { const float invalidScale = getInvalidScale(model.operands[operand].type); const std::string message = "mutateOperandScaleTest: operand " + std::to_string(operand) + " has scale of " + std::to_string(invalidScale); validate(device, message, model, [operand, invalidScale](Model* model) { model->operands[operand].scale = invalidScale; }); } } ///////////////////////// VALIDATE OPERAND ZERO POINT ///////////////////////// static std::vector getInvalidZeroPoints(OperandType type) { switch (type) { case OperandType::FLOAT16: case OperandType::FLOAT32: case OperandType::INT32: case OperandType::UINT32: case OperandType::BOOL: case OperandType::TENSOR_BOOL8: case OperandType::TENSOR_FLOAT16: case OperandType::TENSOR_FLOAT32: case OperandType::TENSOR_INT32: case OperandType::TENSOR_QUANT8_SYMM_PER_CHANNEL: return {1}; case OperandType::TENSOR_QUANT8_ASYMM: return {-1, 256}; case OperandType::TENSOR_QUANT8_SYMM: return {-129, -1, 1, 128}; case OperandType::TENSOR_QUANT16_ASYMM: return {-1, 65536}; case OperandType::TENSOR_QUANT16_SYMM: return {-32769, -1, 1, 32768}; default: return {}; } } static void mutateOperandZeroPointTest(const sp& device, const Model& model) { for (size_t operand = 0; operand < model.operands.size(); ++operand) { const std::vector invalidZeroPoints = getInvalidZeroPoints(model.operands[operand].type); for (int32_t invalidZeroPoint : invalidZeroPoints) { const std::string message = "mutateOperandZeroPointTest: operand " + std::to_string(operand) + " has zero point of " + std::to_string(invalidZeroPoint); validate(device, message, model, [operand, invalidZeroPoint](Model* model) { model->operands[operand].zeroPoint = invalidZeroPoint; }); } } } ///////////////////////// VALIDATE EXTRA ??? ///////////////////////// // TODO: Operand::lifetime // TODO: Operand::location ///////////////////////// VALIDATE OPERATION OPERAND TYPE ///////////////////////// static void mutateOperand(Operand* operand, OperandType type) { Operand newOperand = *operand; newOperand.type = type; switch (type) { case OperandType::FLOAT16: case OperandType::FLOAT32: case OperandType::INT32: case OperandType::UINT32: case OperandType::BOOL: newOperand.dimensions = hidl_vec(); newOperand.scale = 0.0f; newOperand.zeroPoint = 0; break; case OperandType::TENSOR_BOOL8: case OperandType::TENSOR_FLOAT16: case OperandType::TENSOR_FLOAT32: newOperand.dimensions = operand->dimensions.size() > 0 ? operand->dimensions : hidl_vec({1}); newOperand.scale = 0.0f; newOperand.zeroPoint = 0; break; case OperandType::TENSOR_INT32: newOperand.dimensions = operand->dimensions.size() > 0 ? operand->dimensions : hidl_vec({1}); newOperand.zeroPoint = 0; break; case OperandType::TENSOR_QUANT8_ASYMM: case OperandType::TENSOR_QUANT8_SYMM: case OperandType::TENSOR_QUANT16_ASYMM: case OperandType::TENSOR_QUANT16_SYMM: newOperand.dimensions = operand->dimensions.size() > 0 ? operand->dimensions : hidl_vec({1}); newOperand.scale = operand->scale != 0.0f ? operand->scale : 1.0f; break; case OperandType::TENSOR_QUANT8_SYMM_PER_CHANNEL: { newOperand.dimensions = operand->dimensions.size() > 0 ? operand->dimensions : hidl_vec({1}); newOperand.scale = 0.0f; newOperand.zeroPoint = 0; SymmPerChannelQuantParams channelQuant; channelQuant.channelDim = 0; channelQuant.scales = hidl_vec( operand->dimensions.size() > 0 ? static_cast(operand->dimensions[0]) : 0); for (size_t i = 0; i < channelQuant.scales.size(); ++i) { channelQuant.scales[i] = 1.0f; } newOperand.extraParams.channelQuant(std::move(channelQuant)); } break; case OperandType::OEM: case OperandType::TENSOR_OEM_BYTE: default: break; } *operand = newOperand; } static bool mutateOperationOperandTypeSkip(size_t operand, OperandType type, const Model& model) { // Do not test OEM types if (type == model.operands[operand].type || type == OperandType::OEM || type == OperandType::TENSOR_OEM_BYTE) { return true; } for (const Operation& operation : model.operations) { // Skip mutateOperationOperandTypeTest for the following operations. // - LSH_PROJECTION's second argument is allowed to have any type. // - ARGMIN and ARGMAX's first argument can be any of // TENSOR_(FLOAT16|FLOAT32|INT32|QUANT8_ASYMM). // - CAST's argument can be any of TENSOR_(FLOAT16|FLOAT32|INT32|QUANT8_ASYMM). // - RANDOM_MULTINOMIAL's argument can be either TENSOR_FLOAT16 or TENSOR_FLOAT32. // - DEQUANTIZE input can be any of // TENSOR_(QUANT8_ASYMM|QUANT8_SYMM|QUANT8_SYMM_PER_CHANNEL), output can // be of either TENSOR_FLOAT16 or TENSOR_FLOAT32. // - QUANTIZE input can be either TENSOR_FLOAT16 or TENSOR_FLOAT32 // - CONV_2D filter type (arg 1) can be QUANT8_ASYMM or QUANT8_SYMM_PER_CHANNEL // - DEPTHWISE_CONV_2D filter type (arg 1) can be QUANT8_ASYMM or QUANT8_SYMM_PER_CHANNEL // - GROUPED_CONV_2D filter type (arg 1) can be QUANT8_ASYMM or QUANT8_SYMM_PER_CHANNEL // - TRANSPOSE_CONV_2D filter type (arg 1) can be QUANT8_ASYMM or QUANT8_SYMM_PER_CHANNEL switch (operation.type) { case OperationType::LSH_PROJECTION: { if (operand == operation.inputs[1]) { return true; } } break; case OperationType::CAST: case OperationType::ARGMAX: case OperationType::ARGMIN: { if (type == OperandType::TENSOR_FLOAT16 || type == OperandType::TENSOR_FLOAT32 || type == OperandType::TENSOR_INT32 || type == OperandType::TENSOR_QUANT8_ASYMM) { return true; } } break; case OperationType::QUANTIZE: case OperationType::RANDOM_MULTINOMIAL: { if (operand == operation.inputs[0] && (type == OperandType::TENSOR_FLOAT16 || type == OperandType::TENSOR_FLOAT32)) { return true; } } break; case OperationType::DEQUANTIZE: { if (operand == operation.inputs[0] && (type == OperandType::TENSOR_QUANT8_ASYMM || type == OperandType::TENSOR_QUANT8_SYMM || type == OperandType::TENSOR_QUANT8_SYMM_PER_CHANNEL)) { return true; } if (operand == operation.outputs[0] && (type == OperandType::TENSOR_FLOAT16 || type == OperandType::TENSOR_FLOAT32)) { return true; } } break; case OperationType::TRANSPOSE_CONV_2D: case OperationType::GROUPED_CONV_2D: case OperationType::DEPTHWISE_CONV_2D: case OperationType::CONV_2D: { if (operand == operation.inputs[1] && (type == OperandType::TENSOR_QUANT8_ASYMM || type == OperandType::TENSOR_QUANT8_SYMM_PER_CHANNEL)) { return true; } } break; default: break; } } return false; } static void mutateOperationOperandTypeTest(const sp& device, const Model& model) { for (size_t operand = 0; operand < model.operands.size(); ++operand) { for (OperandType invalidOperandType : hidl_enum_range{}) { if (mutateOperationOperandTypeSkip(operand, invalidOperandType, model)) { continue; } const std::string message = "mutateOperationOperandTypeTest: operand " + std::to_string(operand) + " set to type " + toString(invalidOperandType); validate(device, message, model, [operand, invalidOperandType](Model* model) { mutateOperand(&model->operands[operand], invalidOperandType); }); } } } ///////////////////////// VALIDATE MODEL OPERATION TYPE ///////////////////////// static const uint32_t invalidOperationTypes[] = { static_cast(OperationTypeRange::FUNDAMENTAL_MAX) + 1, static_cast(OperationTypeRange::OEM_MIN) - 1, static_cast(OperationTypeRange::OEM_MAX) + 1, }; static void mutateOperationTypeTest(const sp& device, const Model& model) { for (size_t operation = 0; operation < model.operations.size(); ++operation) { for (uint32_t invalidOperationType : invalidOperationTypes) { const std::string message = "mutateOperationTypeTest: operation " + std::to_string(operation) + " set to value " + std::to_string(invalidOperationType); validate(device, message, model, [operation, invalidOperationType](Model* model) { model->operations[operation].type = static_cast(invalidOperationType); }); } } } ///////////////////////// VALIDATE MODEL OPERATION INPUT OPERAND INDEX ///////////////////////// static void mutateOperationInputOperandIndexTest(const sp& device, const Model& model) { for (size_t operation = 0; operation < model.operations.size(); ++operation) { const uint32_t invalidOperand = model.operands.size(); for (size_t input = 0; input < model.operations[operation].inputs.size(); ++input) { const std::string message = "mutateOperationInputOperandIndexTest: operation " + std::to_string(operation) + " input " + std::to_string(input); validate(device, message, model, [operation, input, invalidOperand](Model* model) { model->operations[operation].inputs[input] = invalidOperand; }); } } } ///////////////////////// VALIDATE MODEL OPERATION OUTPUT OPERAND INDEX ///////////////////////// static void mutateOperationOutputOperandIndexTest(const sp& device, const Model& model) { for (size_t operation = 0; operation < model.operations.size(); ++operation) { const uint32_t invalidOperand = model.operands.size(); for (size_t output = 0; output < model.operations[operation].outputs.size(); ++output) { const std::string message = "mutateOperationOutputOperandIndexTest: operation " + std::to_string(operation) + " output " + std::to_string(output); validate(device, message, model, [operation, output, invalidOperand](Model* model) { model->operations[operation].outputs[output] = invalidOperand; }); } } } ///////////////////////// REMOVE OPERAND FROM EVERYTHING ///////////////////////// static void removeValueAndDecrementGreaterValues(hidl_vec* vec, uint32_t value) { if (vec) { // remove elements matching "value" auto last = std::remove(vec->begin(), vec->end(), value); vec->resize(std::distance(vec->begin(), last)); // decrement elements exceeding "value" std::transform(vec->begin(), vec->end(), vec->begin(), [value](uint32_t v) { return v > value ? v-- : v; }); } } static void removeOperand(Model* model, uint32_t index) { hidl_vec_removeAt(&model->operands, index); for (Operation& operation : model->operations) { removeValueAndDecrementGreaterValues(&operation.inputs, index); removeValueAndDecrementGreaterValues(&operation.outputs, index); } removeValueAndDecrementGreaterValues(&model->inputIndexes, index); removeValueAndDecrementGreaterValues(&model->outputIndexes, index); } static bool removeOperandSkip(size_t operand, const Model& model) { for (const Operation& operation : model.operations) { // Skip removeOperandTest for the following operations. // - SPLIT's outputs are not checked during prepareModel. if (operation.type == OperationType::SPLIT) { for (const size_t outOprand : operation.outputs) { if (operand == outOprand) { return true; } } } // BIDIRECTIONAL_SEQUENCE_LSTM and BIDIRECTIONAL_SEQUENCE_RNN can have either one or two // outputs depending on their mergeOutputs parameter. if (operation.type == OperationType::BIDIRECTIONAL_SEQUENCE_LSTM || operation.type == OperationType::BIDIRECTIONAL_SEQUENCE_RNN) { for (const size_t outOprand : operation.outputs) { if (operand == outOprand) { return true; } } } } return false; } static void removeOperandTest(const sp& device, const Model& model) { for (size_t operand = 0; operand < model.operands.size(); ++operand) { if (removeOperandSkip(operand, model)) { continue; } const std::string message = "removeOperandTest: operand " + std::to_string(operand); validate(device, message, model, [operand](Model* model) { removeOperand(model, operand); }); } } ///////////////////////// REMOVE OPERATION ///////////////////////// static void removeOperation(Model* model, uint32_t index) { for (uint32_t operand : model->operations[index].inputs) { model->operands[operand].numberOfConsumers--; } hidl_vec_removeAt(&model->operations, index); } static void removeOperationTest(const sp& device, const Model& model) { for (size_t operation = 0; operation < model.operations.size(); ++operation) { const std::string message = "removeOperationTest: operation " + std::to_string(operation); validate(device, message, model, [operation](Model* model) { removeOperation(model, operation); }); } } ///////////////////////// REMOVE OPERATION INPUT ///////////////////////// static bool removeOperationInputSkip(const Operation& op, size_t input) { // Skip removeOperationInputTest for the following operations. // - CONCATENATION has at least 2 inputs, with the last element being INT32. // - CONV_2D, DEPTHWISE_CONV_2D, MAX_POOL_2D, AVERAGE_POOL_2D, L2_POOL_2D, RESIZE_BILINEAR, // SPACE_TO_DEPTH, SPACE_TO_DEPTH, SPACE_TO_BATCH_ND, BATCH_TO_SPACE_ND can have an optional // layout parameter. // - L2_NORMALIZATION, LOCAL_RESPONSE_NORMALIZATION, SOFTMAX can have an optional axis // parameter. switch (op.type) { case OperationType::CONCATENATION: { if (op.inputs.size() > 2 && input != op.inputs.size() - 1) { return true; } } break; case OperationType::DEPTHWISE_CONV_2D: { if ((op.inputs.size() == 12 && input == 11) || (op.inputs.size() == 9 && input == 8)) { return true; } } break; case OperationType::CONV_2D: case OperationType::AVERAGE_POOL_2D: case OperationType::MAX_POOL_2D: case OperationType::L2_POOL_2D: { if ((op.inputs.size() == 11 && input == 10) || (op.inputs.size() == 8 && input == 7)) { return true; } } break; case OperationType::RESIZE_BILINEAR: { if (op.inputs.size() == 4 && input == 3) { return true; } } break; case OperationType::SPACE_TO_DEPTH: case OperationType::DEPTH_TO_SPACE: case OperationType::BATCH_TO_SPACE_ND: { if (op.inputs.size() == 3 && input == 2) { return true; } } break; case OperationType::SPACE_TO_BATCH_ND: { if (op.inputs.size() == 4 && input == 3) { return true; } } break; case OperationType::L2_NORMALIZATION: { if (op.inputs.size() == 2 && input == 1) { return true; } } break; case OperationType::LOCAL_RESPONSE_NORMALIZATION: { if (op.inputs.size() == 6 && input == 5) { return true; } } break; case OperationType::SOFTMAX: { if (op.inputs.size() == 3 && input == 2) { return true; } } break; default: break; } return false; } static void removeOperationInputTest(const sp& device, const Model& model) { for (size_t operation = 0; operation < model.operations.size(); ++operation) { for (size_t input = 0; input < model.operations[operation].inputs.size(); ++input) { const Operation& op = model.operations[operation]; if (removeOperationInputSkip(op, input)) { continue; } const std::string message = "removeOperationInputTest: operation " + std::to_string(operation) + ", input " + std::to_string(input); validate(device, message, model, [operation, input](Model* model) { uint32_t operand = model->operations[operation].inputs[input]; model->operands[operand].numberOfConsumers--; hidl_vec_removeAt(&model->operations[operation].inputs, input); }); } } } ///////////////////////// REMOVE OPERATION OUTPUT ///////////////////////// static void removeOperationOutputTest(const sp& device, const Model& model) { for (size_t operation = 0; operation < model.operations.size(); ++operation) { for (size_t output = 0; output < model.operations[operation].outputs.size(); ++output) { const std::string message = "removeOperationOutputTest: operation " + std::to_string(operation) + ", output " + std::to_string(output); validate(device, message, model, [operation, output](Model* model) { hidl_vec_removeAt(&model->operations[operation].outputs, output); }); } } } ///////////////////////// MODEL VALIDATION ///////////////////////// // TODO: remove model input // TODO: remove model output // TODO: add unused operation ///////////////////////// ADD OPERATION INPUT ///////////////////////// static bool addOperationInputSkip(const Operation& op) { // Skip addOperationInputTest for the following operations. // - L2_NORMALIZATION, LOCAL_RESPONSE_NORMALIZATION, SOFTMAX can have an optional INT32 axis // parameter. if ((op.type == OperationType::L2_NORMALIZATION && op.inputs.size() == 1) || (op.type == OperationType::LOCAL_RESPONSE_NORMALIZATION && op.inputs.size() == 5) || (op.type == OperationType::SOFTMAX && op.inputs.size() == 2)) { return true; } return false; } static void addOperationInputTest(const sp& device, const Model& model) { for (size_t operation = 0; operation < model.operations.size(); ++operation) { if (addOperationInputSkip(model.operations[operation])) { continue; } const std::string message = "addOperationInputTest: operation " + std::to_string(operation); validate(device, message, model, [operation](Model* model) { uint32_t index = addOperand(model, OperandLifeTime::MODEL_INPUT); hidl_vec_push_back(&model->operations[operation].inputs, index); hidl_vec_push_back(&model->inputIndexes, index); }); } } ///////////////////////// ADD OPERATION OUTPUT ///////////////////////// static void addOperationOutputTest(const sp& device, const Model& model) { for (size_t operation = 0; operation < model.operations.size(); ++operation) { const std::string message = "addOperationOutputTest: operation " + std::to_string(operation); validate(device, message, model, [operation](Model* model) { uint32_t index = addOperand(model, OperandLifeTime::MODEL_OUTPUT); hidl_vec_push_back(&model->operations[operation].outputs, index); hidl_vec_push_back(&model->outputIndexes, index); }); } } ///////////////////////// VALIDATE EXECUTION PREFERENCE ///////////////////////// static const int32_t invalidExecutionPreferences[] = { static_cast(ExecutionPreference::LOW_POWER) - 1, // lower bound static_cast(ExecutionPreference::SUSTAINED_SPEED) + 1, // upper bound }; static void mutateExecutionPreferenceTest(const sp& device, const Model& model) { for (int32_t preference : invalidExecutionPreferences) { const std::string message = "mutateExecutionPreferenceTest: preference " + std::to_string(preference); validate(device, message, model, [](Model*) {}, static_cast(preference)); } } ////////////////////////// ENTRY POINT ////////////////////////////// void ValidationTest::validateModel(const Model& model) { mutateOperandTypeTest(device, model); mutateOperandRankTest(device, model); mutateOperandScaleTest(device, model); mutateOperandZeroPointTest(device, model); mutateOperationOperandTypeTest(device, model); mutateOperationTypeTest(device, model); mutateOperationInputOperandIndexTest(device, model); mutateOperationOutputOperandIndexTest(device, model); removeOperandTest(device, model); removeOperationTest(device, model); removeOperationInputTest(device, model); removeOperationOutputTest(device, model); addOperationInputTest(device, model); addOperationOutputTest(device, model); mutateExecutionPreferenceTest(device, model); } } // namespace functional } // namespace vts } // namespace V1_2 } // namespace neuralnetworks } // namespace hardware } // namespace android